Temporary fasteners

ABSTRACT

A fastener is provided that includes a housing body including a bore extending along a longitudinal axis from a proximal end of the housing body, a housing body anti-rotation part, and a reduced diameter opening at a distal end of the housing body, a collet body partially translating within the housing body bore, having a collet body anti-rotation part positioned at least partially within the housing body, and a plurality of clamping fingers axially extending from a wall portion of the collet body, and a removable bushing positioned at least partially in the housing body bore. Rotation of the collet body is substantially prevented by an interaction between the housing body anti-rotation part and the collet body anti-rotation part during fastener clamping and unclamping and the removable bushing and the reduced diameter opening in the bore prevent escapement of the collet body anti-rotation part from the housing body.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a divisional of U.S. Non-Provisional patentapplication Ser. No. 13/037,349, entitled “TEMPORARY FASTENERS”, andfiled on Feb. 28, 2011. U.S. Non-Provisional patent application Ser. No.13/037,349 is a continuation of International Application No.PCT/US2009/004884 entitled “TEMPORARY FASTENERS”, and filed on Aug. 26,2009. International Application No. PCT/US2009/004884 claims priority toU.S. Provisional Application No. 61/208,188 entitled “TEMPORARYFASTENERS”, and filed on Feb. 20, 2009. International Application No.PCT/US2009/004884 claims further priority to U.S. ProvisionalApplication No. 61/190,215 entitled “TEMPORARY FASTENERS”, and filed onAug. 26, 2008. The entire contents of each of the above-listedapplications are hereby incorporated by reference for all purposes.

SUMMARY OF THE INVENTION

The invention is directed towards temporary fasteners (also known as“tack” fasteners) used to hold, at least temporarily, at least two workpieces together where a portion of the fastener is disposed insubstantially aligned holes or bores formed in the work pieces. In sucha configuration, the outer most work pieces are brought into compressionwith each other either directly or through any intermediary work piecesby portions of the temporary fastener.

Fasteners according to the invention comprise a housing body, a colletbody and a translatable central body. The housing body is configured toreceive both a portion of the collet body and a portion of thetranslatable central body wherein another portion of the collet body anda portion of the housing body provide the work piece contacting surfacesand wherein the translatable central body functions to actively and/orpassively displace and/or converge or restore radially displaceableportions of the collet body.

Collet bodies of the various invention embodiments each define alongitudinal axis and generally comprise a first or distal end defininga first generally circular opening and a second or proximal end defininga second generally circular opening. Adjacent to the first end is afirst wall portion having an inner surface, an outer surface, anddefining at least two secondary slots extending longitudinally from thefirst end to thereby create at least two flexible fingers. Adjacent tothe second end is a second wall portion having an inner surface, and anouter surface.

Depending upon the nature of an invention embodiment, the flexiblefingers can be characterized as having a converging, diverging orconstant progressing radial profile in a nominal or resting state. Asused herein, the term “progressing radial profile” means a series ofradius measurements taken along a segment of the collet body axis to therelevant wall outer periphery. Many embodiments comprise collet bodieswith a converging progressive radial profile for the first wall portion,e.g., the fingers. This profile minimizes the insertion force necessaryto insure that the first or distal end of the collet body extends pastthe most distal work piece, decreases collet body wear, reduces oreliminates undesired work piece deformation, and enhances theremovability of the fasteners from the work pieces.

In addition to the foregoing, a generally annular protrusion extendsfrom the first wall portion, preferably at the first or distal end. Theannular protrusion comprises a leading face and a trailing face, both ofwhich can be characterized as segmented by the secondary slots formed inthe collet body, where the trailing face comprises a portion of thecollet body that is in compressive contact with a work piece duringclamp up. For the reasons expressed above, a converging progressiveradial profile is particularly attractive in embodiments wherein theannular protrusion materially extends from the outer surface of thefirst wall portion.

Separating the collet body first and second wall portions may be a midbody portion. Fastener embodiments of the invention having aparticularly long stroke or working range will also have a mid bodyportion that is comparatively long with respect to embodiments having ashort stroke or working length, which may not have a mid body portion.The collet body may optionally define a primary slot extending from thefirst end and preferably (although not necessarily) to the second end.The primary slot may be parallel to the collet body axis, linear butskew to the axis or helical, depending upon the embodiment.

As intimated above, the nature of the collet body material affects itsperformance. While the collet body can be formed from a myriad ofmaterials, any such materials will have memory properties, malleableproperties, or a combination of the two. A memory material will permittemporary distortion of the collet body fingers until the distortingforce has been removed, where after the affected portions will return totheir initial state or as close to the initial state as possible.Suitable memory materials include spring steel, plastics, composites,and the like. A malleable material will cause a distortion resultingfrom the application of at least one force to permanently alter thephysical state of the affected collet body portion. Suitable malleablematerials include certain steels, aluminum and its alloys, titanium andits alloys, and the like. A combination material will exhibit a hybridresponse, the nature of which depends largely upon the composition ofthe material and its environment of use. The intended application forfasteners comprising collet bodies will generally determine the mostdesirable material composition.

For additional disclosure regarding collet bodies, please refer toInternational Publication No. WO 2003-069971, which is incorporatedherein by reference.

Collet bodies according to the invention that rely upon rotation of thetranslatable central body to effectuate translation/reciprocation of thecollet body within the housing body further comprise a first part of atwo part anti-rotation means (hereinafter “collet body ARM” withspecific reference to the first part, and “ARM” with general referenceto both parts). A variety of ARM arrangements are suitable forcounteracting induced rotation of the collet body within the housingbody; a valid collet body ARM need only use structure of or associatedwith the collet body that compressionally impinges a portion of thehousing body when rotated within at least a portion of the housing bodysuch that further rotation of the collet body is not possible within thedesign limits of the fastener.

One series of embodiments relies upon the incorporation of anon-circular cross section portion of the collet body to function as thecollet body ARM, e.g., (a)symmetrical elliptical, or regular orirregular polygonal cross section. A simple illustration of this form isa key (protrusion) and slot arrangement where the key may be present ona portion of the collet and the slot formed in the housing body, or viceversa. Naturally, a plurality of keys and slots may be used. Thegeometric crosssection of the key may be rectilinear, curvilinear and/orpolygonal. Moreover, while it is preferable that the housing bodybore/hole be complementary in geometry to the key arrangement, it isonly necessary that the bore/hole rotationally interfere with the keyarrangement, but otherwise permit translation of the first part of theARM in the second part, as described below. Thus, for example, there maybe only two key features present on the collet body, but four slotsformed in the housing body. So long as at least one key feature operatesto prevent collet body rotation, it is considered a suitable collet bodyARM.

Another series of embodiments permits the use of collet bodies havingcircular peripheral profiles, but provides for at least one, andpreferably two, radially extending appendages. These appendages or armscan be considered “keys”, but are usually of sufficient radial lengthfrom the collet body so as to require throughbody slots formed in thehousing body, which will be discussed in detail below.

The housing bodies used in various invention embodiments include firstor distal ends and second or proximal ends, by convention, as well asexterior surfaces and interior surfaces. The interior surface of a givenhousing body defines a bore or hole that extends from the proximal endto the distal end, into which a portion of the collet body comprisingthe collet body ARM is operatively located and is permitted to axiallyreciprocate therein. While the bore or hole need not be of constantcross sectional dimensions and/or geometry from one end to the other, inmany embodiments of the invention, this is true. The interior surface ofthe housing body in one series of embodiments further defines a secondpart of the two part ARM (hereinafter “housing body ARM” with specificreference to the second part) while a sectional portion of the housingbody in another series of embodiments defines the housing body ARM.

The housing body also includes a first part of a two part translationarresting means (hereinafter “housing body TAM” with specific referenceto the first part, and “TAM” with general reference to both parts) forpreventing unintentional escapement of the collet body from at least oneend of the housing body where the collet body includes a second part ofTAM (hereinafter “collet body TAM” with specific reference to the secondpart). The housing body TAM generally comprises structure defining anorifice having a diameter less than the collet body TAM, which in manycases comprises the collet body ARM.

Finally, the translatable central bodies found in the various inventionembodiments are disposed in the housing bodies and selectively operateto affect the radially oriented displacement of the collet body fingers.Each translatable central body includes a working portion for contactingthe inside surface of the fingers when axially translated there towards,and a drive portion for receiving rotational and/or axial force(s) thatcause, either directly or indirectly, the working portion to engage withor retract from the collet body fingers.

Due to the interaction between the various fastener components, radialdisplacement of the collet body fingers by the translatable central bodyoccurs when the central body is moved towards the distal end of thehousing. As a consequence, the drive portion of the translatable centralbody is caused to move into the hole/bore of the housing body. At fulltranslation, many invention embodiments have only a minimal portion ofthe central body exposed beyond the second or proximal end of thehousing body. This state is of particular benefit in certainmanufacturing environments wherein minimal fastener height on the toolside is desired or required.

As discussed above with reference to collet bodies with or withoutARM(s), the translatable central body of any given fastener according tothe invention may be subjected to external axially or rotationallyapplied force, the later being transformed into axial movement throughinteraction with a threaded portion of the collet body or linkedstructure. Either of these forces results in movement of the workingportion of translatable central body either towards or away from thecollet body fingers. For reference purposes, the former is referred toherein as axially induced translation of the translatable central bodywhile the latter is referred to herein as rotationally inducedtranslation of the translatable central body.

In axially induced reciprocating fastener embodiments, it is notnecessary to provide an ARM between the collet body and the housingbody - an axial force is applied to the drive portion of thetranslatable central body, which moves the central body towards thecollet body, thereby causing reciprocation over multiple instances ofsuch axial force application. In these invention embodiments, however,it is advantageous to have a biasing means for restoring thetranslatable central body to its initial state of retraction from thecollet body (thereby ensuring that the working portion of the centralbody is not in contact with the inner surfaces of the collet bodyfingers, and that the fastener is immediately ready for use). In manyembodiments, this biasing means comprises a compression spring whereinone end thereof acts on the housing body at the second or distal end,and another end acts on the translatable central body to thereby causemaximum permitted extension of the central body from the collet body.Application of an axial force to the translatable central body inopposition to the spring bias thereby causes compression of the spring,and permits the working portion of the translatable central body toengage with the inner surfaces of the collet body fingers.

In rotationally induced reciprocating fastener embodiments, thetranslatable central body comprises a threaded portion that interactswith the collet body either directly through a complementary structureon/in the collet body or indirectly through a linkage to the colletbody, whereby rotation of the central body results in translation of thecollet body within the housing body. As noted previously, rotationallyinduced reciprocation embodiments will necessarily employ an ARM so thatrotation of the translatable central body translates into axialtranslation (and reciprocation during counter rotation) of the colletbody. In one series of rotationally induced reciprocation embodiments,an interior surface portion of the collet body, usually at or proximateto the second or proximal end, defines threads that are functionallycomplementary to the threaded portion formed on the translatable centralbody. In another series of embodiments, a threaded element such as a nutor collar, is securely affixed to the second or proximal end of thecollet body. An advantage to using a threaded nut is that the outersurface cross sectional profile is a polygon, which beneficially canfunction as a collet body ARM as well as a collet body TAM.

Having broadly described the various components of the several inventionembodiments, specific implementations thereof can be generallycharacterized into several forms, namely, axially operated embodimentsand rotationally operated embodiments, with the latter having internalARM variants and external ARM variant. Each form of the invention hasadvantages over the other, but both share many of the same corecomponents.

Internal ARM series embodiments are generally characterized as having ahousing body with a radially closed interior surface wherein theinterior surface functions as a reactive structure (or second part) ofthe collet body ARM. As such, the internal surface geometry of theinterior surface (i.e., cross section geometry) is sufficientlycomplementary to the collet body ARM to prevent unmitigated rotation ofa collet body therein, and is axially consistent to permit substantialaxial translation within the housing body. Preferably, the interiorsurface has a cross section geometry that is highly complementary to thecollet body ARM such that each portion of the collet body ARM has acorresponding reactive structure at the interior surface of the housingbody.

For example in a first instance, the interior surface of the housingbody has a hexagonal cross section with each facet thereof having adistance from the housing body axis of R_(f). The collet body ARM has arectangular cross section profile where the major axis is ≈2R_(f) and aminor axis of «2R_(f) such that there would otherwise be no rotationallyinterference. When disposed within the housing body and subject torotation, two sides of the collet body ARM would contact the interiorsurface of the housing body while two sides would not; only two of thesix sides of the interior surface of the housing body would thenfunction as reactive structures or the second part of the two part ARM.In a second instance, the collet body ARM has a hexagonal cross sectionprofile that is nominally smaller than the internal dimensions of theinterior surface of the housing body (to permit free translation withinthe housing body). In this case, when disposed within the housing bodyand subject to rotation, portions of all six sides of the collet bodyARM would contact the interior surface of the housing body; portions ofall six sides of the interior surface of the housing body would thenfunction as reactive structures or the second part of the two part ARM.

External ARM series embodiments are generally characterized as having ahousing body with at least one generally axially aligned slot extendingfrom the interior surface to the exterior surface of the housing body toreceive a corresponding number of collet body ARM(s). Instead of findinga reactive structure at the interior surface of the housing body (secondpart of the ARM), the reactive structure is a portion of the sectionalperimeter of the housing body slot, i.e., the wall(s) that define(s) theat least one slot. Of course, it is possible to have both internal andexternal ARM functionality in a single fastener.

For purposes of this patent, the terms “area”, “boundary”, “part”,“portion”, “surface”, “zone”, and their synonyms, equivalents and pluralforms, as may be used herein and by way of example, are intended toprovide descriptive references or landmarks with respect to the articleand/or process being described. These and similar or equivalent termsare not intended, nor should be inferred, to delimit or define per seelements of the referenced article and/or process, unless specificallystated as such or facially clear from the several drawings and/or thecontext in which the term(s) is/are used.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a first invention embodiment shown in afirst state, and comprising a housing body, a collet body andtranslatable central body wherein the anti-rotation means comprisescollet body radially extending members in the form of set screws andtranslatably accommodating slots formed in the housing body;

FIG. 2 is a perspective view of the first invention embodiment shown ina second state;

FIG. 3 is a perspective view of the first invention embodiment shown ina third state;

FIG. 4 is an exploded perspective view of the first invention;

FIG. 5 is an isolated perspective view of the collet body of the firstinvention embodiment;

FIG. 6 is an isolated perspective view of the housing body of the firstinvention embodiment;

FIG. 7 is a first side elevation view of the embodiment of FIG. 6;

FIG. 8 is a plan view in cross section taken substantially along theline 8-8 in FIG. 7;

FIG. 9 is a second side elevation view of the embodiment of FIG. 6;

FIG. 10 is a side elevation view in cross section taken substantiallyalong the line 10-10 in FIG. 9;

FIG. 11A is a side elevation view of a second invention embodiment shownin a first state, and comprising a housing body, a collet body andtranslatable central body wherein the anti-rotation means comprisescollet body surface features in the form of a faceted head and apolygonal inner surface formed in the housing body;

FIG. 11B is a side elevation view in cross section view of theembodiment of FIG. 11A;

FIG. 11C is a perspective view of the embodiment of FIG. 11 A;

FIG. 12A is a side elevation view of the second invention embodimentshown in a second state;

FIG. 12B is a side elevation view in cross section view of theembodiment of FIG. 12A;

FIG. 12C is a perspective view of the embodiment of FIG. 12A;

FIG. 13A is a side elevation view of the second invention embodimentshown in a third state;

FIG. 13B is a side elevation view in cross section view of theembodiment of FIG. 13A;

FIG. 14A is a side elevation view of the second invention embodimentshown in a fourth state;

FIG. 14B is a side elevation view in cross section of the embodiment ofFIG. 14A;

FIG. 15 is an exploded perspective view of the second inventionembodiment;

FIG. 16 is an isolated side elevation view of the housing body of thesecond embodiment;

FIG. 17 is a plan view in cross section taken substantially along theline 17-17 in FIG. 16;

FIG. 18 is a cross section view taken substantially along the line 18-18in FIG. 116;

FIG. 19 is an isolated side elevation view of the collet body of thesecond embodiment;

FIG. 20 is a plan view in cross section taken substantially along theline 20-20 in FIG. 19; and

FIG. 21 is an elevation view in cross section taken substantially alongthe line 21-21 in FIG. 19.

DESCRIPTION OF INVENTION EMBODIMENTS

Preface: The terminal end of any numeric lead line in the severaldrawings, when associated with any structure or process, reference orlandmark described in this section, is intended to representativelyidentify and associate such structure or process, reference or landmarkwith respect to the written description of such object or process. It isnot intended, nor should be inferred, to delimit or define per seboundaries of the referenced object or process, unless specificallystated as such or facially clear from the drawings and the context inwhich the term(s) is/are used. Unless specifically stated as such orfacially clear from the several drawings and the context in which theterm(s) is/are used, all words and visual aids should be given theircommon commercial and/or scientific meaning consistent with the contextof the disclosure herein.

With the foregoing in mind, the following description is presented toenable a person skilled in the art to make and use the claimedinvention. Various modifications to the described embodiments will bereadily apparent to those skilled in the art, and the generic principlesdisclosed herein may be applied to other embodiments and applicationsthereof without departing from the spirit and scope of the presentinvention, as defined by the appended claims. Thus, the claimedinvention is not intended to nor should be limited to the disclosedand/or described embodiments, but is to be accorded the widest scopeconsistent with the principles and features disclosed herein.

Turning then to the several embodiments, wherein like numerals indicatelike parts, and more particularly to FIGS. 1-10, a first embodiment ofthe invention relating to an inexpensive temporary fastener 20 having anexternal or projecting collet body ARM is shown from initial engagementwith a translatable central body in the form of a threaded rod 90 with acol let body 30 (FIG. 1) to a fully clamped-up configuration (FIG. 3).As shown in the various Figures, fastener 20 comprises a collet body 30translatably disposed in housing body 70 and into which threaded rod 90may be rotationally engaged whereby rotation of rod 90 is transformedinto translational movement of collet body 30 in housing body 70.

Collet body 30, best shown in FIG. 5, includes first wall portion 40whereby a plurality of slots 42 defined thereby establish fingers 44that terminate at first or distal end 32 and that comprise protrudingportion 46, each segment of which has leading face 48 and trailing face50. Collet body 30 further includes second wall portion 60, whichdefines holes 64 that extend from outer surface 56 to inner surface 54,and which terminates at second or proximal end 52, and a mid bodyportion 36 there between the first wall portion 40 and the second wallportion 60. Inner surface 54 defines threads 62, which are complementaryto threaded portion 96 of threaded rod 90, thereby permitting threadableengagement there between. A threaded element 79 is also shown in FIG. 5.

Housing body 70, best shown in FIGS. 6-10, includes first or distal end72, second or proximal end 76, inner surface 78, which includes threadedportion 82, the threads of which are complementary to threaded portion96 of threaded rod 90, thereby permitting threadable engagement therebetween, and slots 86 a/b, which will be described in more detail below.Distal end 72 defines reduced diameter bore or opening 74, and therebyestablishes wall 88.

As best shown in FIG. 4, a first part of an external two-partanti-rotation means (“ARM”) is established by engaging set screws 66 a/bwith holes 64, which thereby form a collet body ARM; housing body 70defines, inter alia, the second part of the external two-part ARM,namely, two substantially axially aligned slots 86 a/b sized tofunctionally receive set screws 66 a/b, which thereby form a housingARM. Note that set screws 66 a/b do not interfere with the rotation ofthreaded rod 90, and because of their restricted freedom of movementwithin slots 86 a/b, there is no need to mill or otherwise createsurface features on inner surface 78 of housing body 70 (see FIGS. 6, 8,and 10). Also note that from the time fingers 44 are radially expanded(FIG. 2), thrust washer 94 and drive nut 98 of threaded rod 90 are incontact with proximal end 76 of housing body 70 through maximum stroke(FIG. 3), thereby achieving a very low clamp-up profile.

A feature of the illustrated embodiment is the presence of non-threadedportion 93 on threaded rod 90. As a consequence of feature, rod 90cannot be “backed out” from collet body 30 during normal operation. Aswaged collar or deformed threads can similarly function to preventthreaded disassociation between these components. An additional featureof the illustrated embodiment is the presence of wall 88, whichfunctions as a first part of a two part translation arresting means(“TAM”) by contacting wall 58 of collet body 30's second wall portion56, which functions as a second part of the two part TAM, upon maximumextension of collet body 30 from housing body 70.

Tangible benefits of fastener 30 include a limited parts count,scalability of certain parts for disparate applications, and the use ofreadily available parts as opposed to custom fabricated parts. FIGS.4-10 exemplify many of these benefits. The discrete parts of fastener 20are best shown in FIG. 4. With the exception of collet body 30 andhousing body 70, it can be seen that threaded rod 90 is merely a piecesectioned from a longer continuous threaded rod, that drive nut 98 is aconventional nut that is swaged, welded or, in the illustrated example,fastened via a roll pin to threaded rod 90, and that bushing 100 is aconventional piece as well. And while housing body 70 is preferablymatched to an intended collet body 30, a range of collet bodies andthreaded rods can be accommodated by modifying the internal diameter ofbushing 100 and using col let bodies with standardized second walldiameters, regardless of the diameter of opening 74. In such instances,however, it may be beneficial to introduce another bushing at end 72 toclosely match the working diameter of first wall portion 40.

FIGS. 11A-21 show a second fastener 120 comprising collet body 130,housing body 170, which includes bushing 200, and threaded rod 190 towhich is attached drive nut 198 from initial engagement of threaded rod190 with collet body 130 (FIGS. 11A-C) to a fully clamped-upconfiguration (FIGS. 14A and 148).

Unlike fastener 20, fastener 120 includes an internal ARM, although mostother aspects of the fastener remain similar (for example, collet body130, best shown in FIGS. 19-21, includes first wall portion 140 wherebya plurality of slots 142 defined thereby establish fingers 144 thatterminate at first or distal end 132 and that comprise protrudingportion 146, each segment of which has leading face 148 and trailingface 150, and second wall portion 160, which terminates at second orproximal end 152, while inner surface 154 defines threads 162, which arecomplementary to threaded rod 90, thereby permitting threadableengagement there between. Thus, a first part of an internal two-part ARM(the collet body ARM) comprise facets 166 formed on second wall 160 (seeFIGS. 19-21) while facets 186, which comprise part of inner surface 178of housing body 170, comprise the second part of the external two-partARM (the housing ARM) as is best shown in FIGS. 17 and 18.

Because of machining consequences when forming facets 186, it may benecessary to retrofit housing body 170 with the first part of a two partTAM. Thus, a snap ring may be introduced in recess 188 formed nearhousing body at first or distal end 182 (see FIG. 18) to form this part,as did wall 88 in fastener 20. Similarly, bushing 200 may be necessaryto establish the requisite diameter for receiving rod 190; recess 182 istherefore formed at second or proximal end 176 into which bushing 200may be seated.

What is claimed:
 1. A fastener comprising: a housing body including abore extending along a longitudinal axis from a proximal end of thehousing body, a housing body anti-rotation part, and a reduced diameteropening at a distal end of the housing body; a collet body profiled topartially translate within the housing body bore, having a collet bodyanti-rotation part positioned at least partially within the housingbody, and having a plurality of clamping fingers axially extending froma wall portion of the collet body; a threaded rod including a threadedsection that threadingly engages a threaded section of the collet body;and a removable bushing positioned at least partially in the housingbody bore; where rotation of the collet body is substantially preventedby an interaction between the housing body anti-rotation part and thecollet body anti-rotation part during fastener clamping and unclamping;where the removable bushing and the reduced diameter opening in the boreprevent escapement of the collet body anti-rotation part from thehousing body; where rotation of the threaded rod in opposite directionscauses the collet body to translate in opposing directions withoutrotating in relation to the housing body to induce axial clamping andunclamping and where an axial position of the threaded rod; where thehousing body anti-rotation part includes polygonal cross-sectioncomplimentary profiled with a polygonal cross-section of the collet bodyanti-rotation part and where the housing body includes a wall with aninterior surface that forms the housing body anti-rotation part; andwhere the threaded rod and the collet body are designed to threadinglyengage one another while a portion of the threaded rod is positionedbetween the plurality of clamping fingers and the plurality of clampingfingers extend inwardly toward a collet body axis.
 2. The fastener ofclaim 1, further comprising a drive nut attached a proximal end of thethreaded rod.
 3. The fastener of claim 2, where the drive nut ispositioned axially exterior to the housing body.
 4. The fastener ofclaim 1, where the threaded rod has an axial length equal to or greaterthan a sum of the axial lengths of the housing body and the collet body.5. The fastener of claim 1, where the distal end of the housing body hasa diameter less than a diameter of a head of the collet body.
 6. Afastener comprising: a housing body including a bore extending along alongitudinal axis from a proximal end of the housing body, a housingbody anti-rotation part, and a reduced diameter opening at a distal endof the housing body; a collet body profiled to partially translatewithin the housing body bore, having a collet body anti-rotation partpositioned at least partially within the housing body, and a pluralityof clamping fingers axially extending from a wall portion of the colletbody; a threaded rod threadingly engaged with an inner threaded portionof the collet body, where rotation of the threaded rod in oppositedirections causes the collet body to translate in opposing directions inrelation to the housing body to induce axial clamping and unclamping;and a removable bushing positioned at least partially in the housingbody bore; and a drive nut coupled to a proximal end of the threaded rodand including a lower axial side that is positioned axially above theremovable bushing; where rotation of the collet body is substantiallyprevented during the axial translation by an interaction between thehousing body anti-rotation part and the collet body anti-rotation partduring fastener clamping and unclamping; where the removable bushing andthe reduced diameter opening in the bore prevent escapement of thecollet body anti-rotation part from the housing body; where the housingbody anti-rotation part includes polygonal cross-section complimentaryprofiled with a polygonal cross-section of the collet body anti-rotationpart and where the housing body includes a wall with an interior surfacethat forms the housing body anti-rotation part; and where the threadedrod and the collet body are designed to threadingly engage one anotherwhile a portion of the threaded rod is positioned between the pluralityof clamping fingers and the plurality of clamping fingers extendinwardly toward a collet body axis.
 7. The fastener of claim 6, wherethe drive nut has a polygonal cross-section.
 8. The fastener of claim 6,where the removable bushing has an annular shape.
 9. A fastenercomprising: a housing body including a bore extending along alongitudinal axis from a proximal end of the housing body, a housingbody anti-rotation part, and a reduced diameter opening at a distal endof the housing body; a collet body profiled to partially translatewithin the housing body bore, having a collet body anti-rotation partpositioned at least partially within the housing body, and a pluralityof clamping fingers axially extending from a wall portion of the colletbody; and a threaded rod threadingly engaged with an inner threadedportion of the collet body and a threaded portion of the housing body,where rotation of the threaded rod in opposite directions causes thecollet body to translate in opposing directions in relation to thehousing body to induce clamping and unclamping; a removable bushingpositioned at least partially in the housing body bore; and a drive nutcoupled to a proximal end of the threaded rod and positioned axiallyabove the removable bushing; where rotation of the collet body issubstantially prevented during the axial translation by an interactionbetween the housing body anti-rotation part and the collet bodyanti-rotation part during fastener clamping and unclamping; where theremovable bushing and the reduced diameter opening in the bore preventescapement of the collet body anti-rotation part from the housing body;where the housing body anti-rotation part include a plurality of facetscomplimentary profiled with a plurality of facets in the collet bodyanti-rotation part; where the plurality of clamping fingers extendinwardly toward the longitudinal axis of the fastener in an unclampedconfiguration and are radially expanded in a clamped configuration;where the housing body anti-rotation part includes polygonalcross-section complimentary profiled with a polygonal cross-section ofthe collet body anti-rotation part and where the housing body includes awall with an interior surface that forms the housing body anti-rotationpart and an exterior surface that has a polygonal cross-section; wherethe threaded rod and the collet body are designed to threadingly engageone another while a portion of the threaded rod is positioned betweenthe plurality of clamping fingers and the plurality of clamping fingersextend inwardly toward a collet body axis.
 10. The fastener of claim 9,where the drive nut is positioned axially exterior to the housing body.